1. Network Addressing Issues in 1994 http://www.ralphb.net/IPSubnet/ http://www2.rad.com/networks/19 94/err_con/crc.htm

2. What was going on TCP/IP had pretty much become THE protocol. –TCP/IP made it easy to go global. Organizations were encouraged to get unique global addresses. –(+) Don’t have to worry about reassigning addresses when connecting outside the LAN. –(-) Addresses were handed out willy-nilly.

3. TCP/IP Address Classes There are 5 different address classes. –You can determine which class any IP address is in by examining the first 4 bits of the IP address. Class A addresses begin with 0xxx (1 to 126) Class B addresses begin with 10xx (128 to 190) Class C addresses begin with 110x (192 to 223) Class D addresses begin with 1110 (224 to 239) Class E addresses begin with 1111 (240 to 254)

4. TCP/IP Address Classes Addresses beginning with 01111111, or 127 decimal, are reserved for loopback and for internal testing on a local machine. – [You can test this: you should always be able to ping 127.0.0.1, which points to yourself] Class D addresses are reserved for multicasting. Class E addresses are reserved for future use. They should not be used for host addresses.

5. The Problem Class B address space was (still is) in danger of exhaustion. –More than half the Class B address space was gone. Lack of appropriate-size network numbers for mid-size organizations. –Class B gives you 65,535 hosts –Class C gives you 254 hosts A lot of Class B networks were not fully utilized.

6. State of the TCP/IP Addresses (1994) Over 50% of the Class B addresses gone 6% of the Class C networks assigned. Exhaustion was expected around 2008 Max number of computers: ~4.3 billion

7. Adding to the Problem For Internet routers to move packets across the Internet they needed to know where the networks were. The explosion of networks had created problems for routers that must keep track of all of these networks. The number of networks to keep track of was doubling roughly every 10-12 months.

8. How Routers Functioned IP addresses are 32 bits wide and normally we see them written as four decimal numbers separated by dots. (i.e. 232.134.15.90) This address is split into a host part and a network part. –The network is normally the LAN the host lives on. Thus routers can do their job just by dealing with the network part of the address.

9. State of the Routers (1994) With the existing network routers were in danger of being overwhelmed. Because of design all Internet routers had to have a list of all networks, all were faced with the same problem. –The NSFnet routers were able to handle 25,000 network entries….they had 19,400 listed networks with 7,400 additional networks unlisted.

10. Problem Specifics The problem is this: –There are 126 usable Class A networks –There are around 32,000 usable Class B networks –There are over 2 million Class C networks

11. Solving the Routing Problem

12. Solutions – Short Term Development of new routing protocols for interdomain routing. –Basically a special set of protocols for routing between the Internet network service providers. Assign IP network numbers based on the Internet topology. –Instead of handing out IP addresses willy-nilly we now group them together.

13. Network Topology Instead of looking at the whole network address, a router will only look at one part. Example: We send a message to 232.134.15.90. –Before we would see that it is a Class C network and the router would route it to the 232.134.15 network. –Now the first router sends it to the 232 network router. The 232 network router sends it to the 134 network router and so on.

14. Solving the Address Space Problem (Short Term)

15. Conserving the address space A short term solution is to increase utilization of the existing network classes. –All Class B networks allow for some 65,000 hosts. –However a lot of those networks have a large number of unused hosts. By creating subnets within the existing networks can better utilize the existing system.

16. Creating Subnets (General Version) Since the IP address is divided into a network and host part, to subdivide a network we need to extend the network part into the host part. –This extension is called the subnet. First any subnet or hosts numbered “0” or “-1” are considered special. –Broadcast and designation of “this” host. So if we had 4 usable addresses in a subnet, 2 would automatically be lost.

17. Creating Subnets (Details) Remember which part of the IP address belongs to the network (N) and which part belongs to the node (n). A: NNNNNNNN.nnnnnnnn.nnnnnnn.nnnnnnn B: NNNNNNNN.NNNNNNNN.nnnnnnnn.nnnnnnnn C: NNNNNNNN.NNNNNNNN.NNNNNNNN.nnnnnnnn Example: 140.179.240.200 is a Class B address so by default the Network part of the address is defined by the first two octets (140.179.x.x) and the node (or host) part is defined by the last 2 octets (x.x.240.200).

18. Creating Subnets In order to specify the network address for a given IP address, the node section is set to all "0"s. –Example: 140.179.0.0 specifies the network address for 140.179.240.200. When the node section is set to all "1"s, it specifies a broadcast that is sent to all hosts on the network. –140.179.255.255 specifies the example broadcast address. Note that this is true regardless of the length of the node section.

19. Subnet Masking To identify the network and node parts of the address you apply a subnet mask to an IP address. –The network bits are represented by the 1s in the mask, and the node bits are represented by the 0s. –Performing a bitwise logical AND operation between the IP address and the subnet mask results in the Network Address. Example using our test IP address/default Class B subnet mask: 10001100.10110011.11110000.11001000 (140.179.240.200) 11111111.11111111.00000000.00000000 (255.255.000.000) --------------------------------------------------------- 10001100.10110011.00000000.00000000 (140.179.000.000)

20. Default Subnet Masks Class A –11111111.00000000.00000000.00000000 Class B –11111111.11111111.00000000.00000000 Class C –11111111.11111111.11111111.00000000

21. Creating Our Own Masks Additional bits can be added to the default subnet mask for a given Class to further subnet, or break down, a network. When a bitwise logical AND operation is performed between the subnet mask and IP address, the result defines the Subnet Address –Also called the Network Address or Network Number.

22. Restrictions There are some restrictions on the subnet address. –Node addresses of all "0"s and all "1"s are reserved for specifying the local network (when a host does not know it's network address) and all hosts on the network (broadcast address), respectively. –A subnet address cannot be all "0"s or all "1"s. This also implies that a 1 bit subnet mask is not allowed. –This restriction is required because older standards enforced this restriction. Recent standards that allow use of these subnets have superseded these standards, but many "legacy" devices do not support the newer standards. If you are operating in a controlled environment, such as a lab, you can safely use these restricted subnets.

23. Example 10001100.10110011.11011100.11001000 (140.179.220.200) 11111111.11111111.11100000.00000000 (255.255.224.000) -------------------------------------------------------- 10001100.10110011.11000000.00000000 (140.179.192.000) Broadcast Address –10001100.10110011.11011111.11111111 (140.179.223.255) In this example a 3 bit subnet mask was used. –There are 6 (23-2) subnets available with this size mask (remember that subnets with all 0's and all 1's are not allowed). Each subnet has 8190 (213-2) nodes. Each subnet can have nodes assigned to any address between the Subnet address and the Broadcast address. This gives a total of 49,140 nodes for the entire class B address subnetted this way. Notice that this is less than the 65,534 nodes an unsubnetted class B address would have.

24. Summary You can calculate the Subnet Address by performing a bitwise logical AND operation between the IP address and the subnet mask, then setting all the host bits to 0s. Similarly, you can calculate the Broadcast Address for a subnet by performing the same logical AND between the IP address and the subnet mask, then setting all the host bits to 1s. That is how these numbers are derived in the example above.

25. Detailed Example Say you are assigned a Class C network number of 200.133.175.0 You want to utilize this network across multiple small groups within an organization. You can do this by subnetting that network with a subnet address. We will break this network into 14 subnets of 14 nodes each. This will limit us to 196 nodes on the network instead of the 254 we would have without subnetting, but gives us the advantages of traffic isolation and security. To accomplish this, we need to use a subnet mask 4 bits long. –Recall that the default Class C subnet mask is 255.255.255.0. –Extending this by 4 bits yields a mask of 255.255.255.240

26. Detailed Example This gives us 16 possible network numbers, 2 of which cannot be used:

27. Combing Routing and Subnetting CIDR -- Classless InterDomain Routing. –CIDR was invented several years ago to keep the internet from running out of IP addresses. The "classful" system of allocating IP addresses can be very wasteful; anyone who could reasonably show a need for more that 254 host addresses was given a Class B address block of 65533 host addresses. Only a tiny percentage of the allocated Class A and Class B address space has ever been actually assigned to a host computer on the Internet.

28. Combing Routing and Subnetting People realized that addresses could be conserved if the class system was eliminated. By accurately allocating only the amount of address space that was actually needed, the address space crisis could be avoided for many years. This was first proposed in 1992 as a scheme called Supernetting. Under supernetting, the classful subnet masks are extended so that a network address and subnet mask could, for example, specify multiple Class C subnets with one address.

29. Example 11000000.00111100.10000000.00000000 (192.60.128.0 ) 11000000.00111100.10000001.00000000 (192.60.129.0 ) 11000000.00111100.10000010.00000000 (192.60.130.0) 11000000.00111100.10000011.00000000 (192.60.131.0) -------------------------------------------------------- Supernetted Subnet address –11111111.11111111.11111100.00000000 (255.255.252.0) Broadcast address –11000000.00111100.10000011.11111111 (192.60.131.255) In this example, the subnet 192.60.128.0 includes all the addresses from 192.60.128.0 to 192.60.131.255.

30. Notation Notes Under CIDR, the subnet mask notation is reduced to a simplified shorthand. Instead of spelling out the bits of the subnet mask, it is simply listed as the number of 1s bits that start the mask. Example: Instead of writing the address (192.60.128.0.0 and subnet mask (255.255.252.0) the network address would be written simply as: 192.60.128.0/22. –which indicates starting address of the network, and number of 1s bits (22) in the network portion of the address. If you look at the subnet mask in binary (11111111.11111111.11111100.00000000), you can easily see how this notation works. –The use of a CIDR notated address is the same as for a Classful address. Classful addresses can easily be written in CIDR notation (Class A = /8, Class B = /16, and Class C = /24)

31. Private Subnets There are three IP network addresses reserved for private networks. The addresses are 10.0.0.0/8, 172.16.0.0/12, and 192.168.0.0/16. They can be used by anyone setting up internal IP networks, such as a lab or home LAN behind a NAT or proxy server or a router. It is always safe to use these because routers on the Internet will never forward packets coming from these addresses. These addresses are defined in RFC 1918.RFC 1918

32. Assigning IP Addresses It is currently almost impossible for an individual or company to be allocated their own IP address blocks. You will simply be told to get them from your ISP. The reason for this is the ever-growing size of the internet routing table. –Just 10 years ago, there were less than 5000 network routes in the entire Internet. –Today, there are over 100,000. Using CIDR, the biggest ISPs are allocated large chunks of address space (usually with a subnet mask of /19 or even smaller); the ISP's customers (often other, smaller ISPs) are then allocated networks from the big ISP's pool. –That way, all the big ISP's customers (and their customers, and so on) are accessible via 1 network route on the Internet.

33. Long Term Changes It is expected that CIDR will keep the Internet happily in IP addresses for the next few years at least. After that, IPv6, with 128 bit addresses, will be needed. Under IPv6, address allocation would comfortably allow a billion unique IP addresses for every person on earth! The complete and gory details of CIDR (released in September 1993) are documented in: http://www.faqs.org/rfcs/rfc1519.html.http://www.faqs.org/rfcs/rfc1519.html